Method and apparatus for earth borehole investigating and signaling



Feb. 28, 1961 o, M JOHANNESEN 2,973,505

METHOD AND APPARATUS FOR EARTH BOREHOLE INVESTIGATING AND SIGNALING Filed Oct. 18, 1954 2 Sheets-Sheet l 52 nvt e www s ma.. ,t 2 W Ew ma un E R O B H Feb- 28, 1961 o. M. JoHANNEsEN METHOD AND APPARATUS FOR EART INVESTIGATING AND SIGNLING Flled 00':l 18, 1954 Jia/5 5u4 503 safe Sw/ 5100 #GLUT METHOD AND APPARATUS FOR EARTH BORE- HOLE INVESTIGATING AND SIGNALING Oddvar M. Johannesen, Arcadia, Calif., assignor, by mesne assignments, to Dresser Industries, inc., Dallas, Tex., a corporation of Delaware Filed Oct. 18, 1954, Ser. No. 462,718

6 Claims. (Cl. 340-18) inaccessible location of the investigation within the borehole, to a convenient accessible point outside the borehole, usually at the surface of the earth, for detection, decoding andlan'alysis of the information thus obtained. In a still more specic aspect, the present invention'relates to improvements in apparatus for measuring at an inaccessible location, electrical quantities by comparison methods; as, for example, by bridge and potentiometer methods.

In certain respects the present invention relates to and presents improvements upon an invention disclosed in an application filed on even date herewith by Robert Lee Alder, Serial No. 462,724, now Patent No. 2,901,685, issued August 25, 1959. Also, in certain respects the present invention relates to and presents improvements upon an invention disclosed in an application tiled on even date herewith by Robert J. Dwyer, Serial No. 462,917.

'f It is well known in the electrical and allied arts to employ a Wheatstone bridge network in measuring an unknown electrical quantity. For example, in measuring electrical resistance this is usually done by passing an electric current through a network of resistances including the resistance of unknown value and varying one of the other resistances of known value by known increments or-steps until the potential between certain points of the network falls to zero value, whereupon, by application of Ohms law and the values of the known resistances, the unknown value of resistance may be computed. The present invention provides a novel apparatus and a new mode for measuring unknown values of resistance and other physical or electrical quantities, automatically and at inaccessible locations, with a great saving in power as compared to previous apparatus and modes of the mentioned character. In many instances in which it is desired -to obtain measurements of the types hereinabove indicated, the problem of an adequate and economical power supply becomes acute, due to the distance between the measuring apparatus and operating personnel, excessive heat, vibration and lack of space at the measuring location, and other factors. This is especially true in the case of earth borehole investigations, wherein the permissible space in the borehole for the investigating apparatus is severely restricted, and the ambient temperatures are often very high. The problem is even more acute in the.

case of apparatus employed in investigations conducted inl the vicinity of the bottom of a deep earth borehole, such as an oil well, during drilling of the hole. In the latter type of operation it is impractical to employ elec- 2,973,55 Patented Feb. 2S, 196i tric conductors to convey electric power to the measuring apparatus at the bottom of the borehole; and resort is had to compact electric batteries contained in the investigating apparatus in the lower end portion of the dnill string adjacent the bottom of the borehole. These batteries, due to their having to be specially constructed to operate under the adverse conditions of extreme heat and vibration encountered in the drilling apparatus, are very expensive, yet of relatively short effective life. With these facts in view, it is an important object of the present invention to provide improvements in apparatus of the class hereinabove mentioned, which will elect considerable savings in the power required for operation.

Another object of the invention is to provide improvements in earth borehole investigation apparatus.

Another object of the invention is to provide an eicient automatically acting apparatus for logging information at a relatively inaccessible location in an earth borehole du'ring drilling thereof.

Another object of the invention is to provide in an earth borehole logging system a means for measuring the unknown value of a physical quantity and encoding a number representing the measured value, formulating a signal representing the encoded number, and transmitting the signal, concurrently with the measuring operation. En-

coding of the number permits much greater accuracy and efficiency in the operation of the system than is attained by other logging systems.

Another object of the invention -is to provide a borehole investigating and signaling system of very low power requirements and capableof operation during 4continued drilling of the borehole.

Another object of the invention `is to provide an apparatus for use at an inaccessible location in an earth borehole for measuring by comparison an unknown value of an electrical quantity, using but a very small amount of electric power.

The above and other important objects and advantages of the invention in its several aspects will become apparent from a thorough consideration of the following description and explanation of the operation of a preferred embodiment of apparatus illustrating a system according to the invention, -in connection with the accompanying drawings diagrammatically depicting said apparatus. In the drawings:

Fig. 1 is a schematic drawing principally in the forni of a circuit diagram of the electrical connections of elec'- trical components of apparatus of the exemplary embodiment according to the invention, and indicating the environment of the apparatus in operation;

Fig. 2 is a schematic drawing depicting in simplified form and `arrangement the circuitry of portions ofthe apparatus of Fig. 1 at a period of its operation devoted to measurement and coded signaling of an unknown value of electrical resistance; and

Fig. 3 is a simplified schematic drawing similar to Fig. 2 but depicting the circuitry of portions of the apparatus of Fig. 1 at a different period of operation, devoted to measurement and coded signaling of an unknown value of electrical potential.

Referring to the drawings, a preferred form of system according to the invention is illustrated in connection with apparatus employed in drilling an earth borehole; and more specifically is illustrated as a system adapted for obtaining within a drill collar adjacent a drill bit at an inaccessible location in a borehole, either during drilling or during periods of suspension of -drilling, measurements of the unknown resistance of an earth-path and of the earths natural potential (N P.) thereadjacent; :and for encoding numbers respectively representing each of the j measurements and formulating and transmitting pluralelement signals representing the encoded ntun'bers.v

Such measurements are of value in electrically logging earth boreholes. The purpose of encoding the number representing the measured value in each instance, is to facilitate transmission of the data or information by signals to -an accessible point outside the borehole and to enhance the accuracy and speed of the signaling, the encoding permitting easy and precise transmission of any of a wide range of numerical values with a minimum number of signal elements in a single value-representing signal. The number to be encoded may be either the actual numerical Value of the measure of the physical quantity being investigated, or may be that value plus or minus a predetermined amount or number, or the like, according to the arrangement, nature and values of the elements of the apparatus; but the encoded number is such that it accurately represents the numerical value of the measure of the quantity; and the apparatus is such that when a signal is formulated from the encoded nurnber, transmitted, received and translated, the translation will yield precisely such number. From the translation an accurate determination of the original measure is then readily effected.

The plural-element signal representing an encoded number representing a value or measure is according to the invention preferably but not necessarily formed in the nature of a series of time-spaced signal-elements each selected from signal-elements of two types or characters. For example, the two types of signal-elements may be, respectively: (l) a current pulse, and (2) absence of a current pulse, Vin which case the signal may be composed of a series of time-spaced current pulses and/ or absences of a current pulse. The nature of this signal and its formation, and of a second type of signal employed for transmitter-receiver synchronization purposes, are hereinafter more fully explained. The signal preferably includes elements in number equal to the number of code symbols required to encode the number representing the measure of the unknown value, for reasons hereinafter made apparent. The encoding is effected in accordance with a known mathematical system of number representation, and is preferably but not necessarily effected or performed in accord with the binary system of number representation, `for reasons hereinafter made fully apparent.

The apparatus of the invention required at the inaccessible location in a borehole is principally housed in a suitable container (not shown) situated and mounted in a lower section of the drill string, as for example, in a drill collar. Being composed principally of well known electrical units such as switches, relays, batteries, electron tubes, capacitors, resistors, conductors and the like, of each of which there is a wide selection of commercially available models, the apparatus of the disclosed embodiment of the invention is only schematically illustrated. It will be understood that the various circuit elements may be widely varied in form and style within the concept of the invention, their selection being largely dependent upon the particular environment Yin which the physical apparatus is to be used. The container and its mounting may be of any suitable design and such as are known in the art.

Referring to Fig. l, a typical earth borehole Bh is indicated as in the process of being drilled in the earth by drilling means including a drill string Ds having a drill bit Db at its lower end. With the exception of the apparatus of the invention housed in the aforementioned container in the lower section of the drill string, the drilling means may be of any suitable type and may be of the well known type employed in rotary drilling. Since the drilling means per se are well known, they are not fully illustrated in the drawings. The apparatus housed in the container (not shown) in a lower section of the drill string, is shown in diagrammatic form outside the borehole in Fig. 1, but it will be understood that the physical apparatus itself is contained within the contines of the drill string. The apparatus thus diagrammatically depicted includes a principal battery B1 which is employed to furnish the power for the principal moving parts of the apparatus, including a timer Ti which governs timing of the operation `of the apparatus. The timer is devised to provide periodic pulses of .power or current from battery B1 to the magnet or motor coil LIC of a rotary stepping switch assembly indicated generally by ordinal L1 and employed to effect switching and other governing .operations of portions of the apparatus. Switch assembly L1 is thereby stepped by the pulses of power rfrom station to station at regular intervals which may be, for example, one second each in duration. Stepping switch assembly v L1 comprises in addition to its stepping motor mechanism, a series of superposed and coaxial, rotary, multicontact switches, L1S1, L1S2, L1S3, L1S4, LISS and LlS, all of which are Vstepped substantially in synchronism from one contact or station to the nexteach time the motor coil receives an actuating current pulse. Each of the several switches L1S1, LlSZ, etc., comprises a sweep contact on an insulated sweep contact arm which is secured to and insulated from a shaft rotated stepwise by the motor, and a circularly disposed series of stationary peripheral contacts on a wafer-type mount, whereby the sweep contact at each step breaks Contact with one peripheral contact or station and makes contact with the next contact or station. The shaft or mechanical driving interconnection of the several switches of the assembly `is indicated by a broken line interconnecting the switches and coil LIC as is conventional in electromechanical diagrams. In the assembly L1 of rotary switches, twelve peripheral contacts or stations are provided for each switch except the first, and the sweep contacts accordingly make one cycleor revolution each twelve seconds when the timer provideslone driving pulse per second. In the drawings, the peripheral contacts are indicated as respective lseries of circularly disposed dots arranged about the inner end of the respective sweep contact arm as an axis; and the sweep contact arms are indicated as radially directed arrows contacting one or another of the respective associated peripheralV contacts. The contacts or stations of the several switches of the L1 assembly are identically numbered as are the hours gures on a time clock, as indicated at switch L1S2 in Fig. 1; and the sweep contacts step or rotate clockwise. The stations of the several switches of a second rotary switch assembly L2 are similarly identically numbered from 1 through 18, as indicated at switch L2S7 at the top of Fig. 1. The sweep contacts of this switch assembly likewise step or rotate in a Aclockwise direction as viewed in the drawings. Any suitable type of rotary stepping switch assembly may be employed for units L1 and L2. One example of a suitable commercially available type of rotary stepping switch assembly is that manufactured by G. H. Leland, Inc., Dayton, Ohio, and illustrated in Patent No. 2,496,880. Y

v Timer T comprises a conventional electronic oscillator stage, designated Osc, which may, for example, be of the phase-'shift ty-pe employing four sections in the phaseshifting network to secure stable operation over a wide range of electron tube element voltages. The oscillator stage may comprise a self-contained amplifier. The output of the oscillator stage is applied to a relay device comprising one or more relays and herein illustrated as a single relay Ryl. Tlhe oscillator is designed to produce an output-of xed frequency, preferably one cycle per second, and a tube in the output stage is biased to pro duce discrete output pulses of current at the rate of one pulse per second. The output pulses energize kcoil RylC of relay Ryl, whereby switch PcylSl of the relay periodically closes and opens at a rate ofy one vcycle per second.

To conserve power, there may be connected in the power supply circuit of battery B1 au flow switch Fs whichj is automatically closed lin the herein disclosed embodiment` getragene ofthe apparatus bythe pressure of drilling liuid passing through the drill string Ds of the drilling means; and which automatically opens when certain conditions, such as. lack of fluid ow, exist. When this or an equivalent switch is closed, or when a parallel connection is closed through a homing Wafer switch L1S1 of rotary switch assembly L1, closure of switch RylSl of relay Ryl permits current to flow. from B1 through conductors 20 and 21, Aswitch RylSl, conductor 22, cam-actuated switch LIK, conductor 23, motor coil L1C of the motor of assembly L1, ground (GND), and switch Fs an'd/or switch L1S1, to B1. Thus the rotary parts of switch assembly L1 are stepped forward (clockwise) one step'.

As this step is taken, switch LIK is opened by its motor operated cam, but sufficient current continues to ow through a holding resistor LlR to hold the switch motor advanced, until the timer relay Ryl opens its switch Ry1S1. As the latter opens, the motor of switch assembly L1 returns or retracts preparatory to taking another step. Thus the switches of assembly L1 are, once per second, advanced one contact or station and the driving means retracted preparatory to advancing another step.

As an aid in conciseness and clarity in the description and tabulation of operations of the structural and electrical apparatus of the herein disclosed embodiment of the apparatus, various circuit elements and parts of the apparatus will hereinafter be referred to principally by way of abbreviated names and designations. example, the circuit through switch L1S3 of assembly L1 when the switch is at its fifth station or contact, will beiudicated by the expression L1S3(5), other switch stations being designated by the number of the station enclosed'in parentheses. Similarly, electric conductors will be designated by ordinary numerals; relays Y`by the expression Ry -followed by a number; a relay coil by the letter C following the relay designation; resistors by the letter R followedA by a number; capacitors bythe letter Q followed by a number; batteries by the letter B followed by a number; etc., as indicated on the drawings and as will hereinafter become fully evident.

Control of switch or relay contacts by electromagnets or the like is indicated on the drawings by light dashed lines connecting the magnet or relay coil with the switch or-contacts, as is conventional. '-Referring to Fig.- l, it will be noted that the second rotary stepping switch assembly, L2, is stepped forwardly one step each time switch assembly L1 steps to station (4), the stepping power circuit for L2 being: B1, 20, 21, RylSl, 22, LIK, 24, L1S2(4), 25, 26, L2K, 27, L2C and GND. Itwill be noted that as L1 steps to (4), timer relay Ryl is closed, and LlK closes; and that both the flow switch Fs and switch L1S1 are closed at this period. These periodic stepping operations of switch assembly L2 serve to perform switching and other functions according to a definite sequence hereinafter tabulated and explained.' Measurement of unknown resistance values is effected by a comparison method using a special form of Wheatstone bridge network Br whose circuitry is traceable on Fig. l, but most readily traced on Fig. 2. The network comprises in its upper left arm resistor R23 and a part o'f an adjusting resistor R22; in its upper right arm, R24; and in its lower left arm, which may be termed the comparison arm, are the other part of R22, R21 and various combinations of resistances obtainable from an array or arrangement of series-connectedresistors R5, R4 R1, R0, which form comparison elements of graded and related values, as hereinafter explained. Thebridge network has in its lower right arm the unknown value 'of resistance (in this case the resistance ofpan earth path between ldrillbit Db and a relatively remoteh ground connection), in series with a resistor R13. AcrossA adiagonal of the network, from junction A to junction B, there is provided an output circuit comprising series onnectedresistors R26 .and R25, from the junction D For of which is taken an. output line through a capacitor Q6 and conductor 56. Resistors R5, R4 R0 are inidividually connectible in the lower left arm of the bridge network by movement of respective elements of two-position switches Sw5Sw4 Sw0, each individually assocated with a respective one of the resistors and arranged to short-circuit its associated resistor when in a first position. When the respective resistor is thus short-circuited, it is, in effect, electrically removed or withdrawn from the network, although still physically connected in series with the other resistors of the group. The elements of switches SwS, Sw4. Sw0 arefurther so constructed and arranged that each is in turn moved to a second position by mechanical connection `with the motor, means of rotary stepping switchv L2, as indicated on Fig. l by the dashed line. The arrangement is such that SwS is moved from its first to second position first, as L2 steps to station (1); Sw4 is the next to be similarly moved, as L2 steps to (2); and so on until each of switches SwS Sw0 has been thus moved. Means in the form of a reject solenoid Sol, (Fig. l') is provided to reversely move or return any of switches Sw5 Sw0, each in turn and immediately after its opening, in the event it is desirable to again short circuit 'the associated resistor to remove or withdraw it from the bridge network, as will presently be more fully explained.

In commencing measurement of the unknown value of resistance, switch SwS is opened as L2 steps to station (1), electrically inserting the associated resistor R5 in the balancing arm of the bridge network. If this resistor isof value such as to cause overbalancing of the bridge, that is, is greater than necessary to cause the network to become balanced, itsassociated'switch, SWS; is returned to its rst position by means including solenoid- Sol,-as hereinafter described. However, if R5. is deter-v mined, by discriminating' means also hereinafter den scribed, to be of value only sufficient to balance the net work, or; insuicient to balance the network, the asso ciated switch SwS is left in second position, leaving R5. effectively connected or retained in the bridge network balancing arm. The described action is repeated with respect to the remaining resistors R4, R3 R0, each in its turn, until each has been tried in the balancing arm of the network by movement of its associated switch to second position, and either retained therein or re-A jected (that is, electrically withdrawn or removed from the network), by return movement of the associated switch to first position. By selecting the ohmic values of resistors R5 R0, of suitably graded and progressively decreasing values interrelated in a manner herein-V after` morefullyexplained and such that R5 is greater than R4, R4 greater than R3, etc., it will be seen that by the time each of the resisto-rs has been tried in the network and retained or rejected, the network will vhave been balanced to within of the value of .resistor R0. Similarly, it will :be noted that' the unknown value of resistance will have been matched to within 150% of the value of the resistor of lowest value in the series.

For facility in explaining the operation of the bridge network, resistors R5 R0 are given hypothetical serial numbers as indicated on the drawings, and the' resistors are, as previously indicated, tried in the bridge4 network balancing arm in inverse order of their respec' tive serial numbers, that is, highest serial number, cor-y responding to highest'resistance value, first, and so on. While many physical arrangements of comparison elements or resistors R5 R0 may be used, and comparison elements of various orders of selected values, it

is preferredito employ resistors of'values V mathematicab' ly interrelated in accordance with the formula V=C2n wherein Vis'the resistonvalue (as in ohms, for example), C is a constant dependent-r upon circuit element values, and n is the serial number of the resistor inthe series-y connectedarray indicated, and is one of a group of consecutive-whole numbers equal in number -t'o the number 7 of resistors R5 R0. It will be noted that the serial numbers need. not be physically applied to the resistors; and that the -resistors need not be actually series-con-l nected in the particular order of their serial numbers, as long as they are selected and tried in the bridge network arm in order of decreasing value, that is,- highest-valued resistor rst, and so on down to lowest-valuedresistor last.

With resistors R5 R0 of graded Y.andinterrelatec'l values according to the formula above indicated, and tried in the bridge network in the lorder mentioned by successive steps of assembly L2, the varrangement is such that the totalohmic value of rsistances R5 R0 `left effective in the bridge arm is 'readily encoded or read out by noting which of switches SwS Sw() are in rst position and which are inseeond position, and assigning zero value to each switch in first position and to each switch in second position a value corresponding to or representing that of its associated resistor. Also, with resistors selected in accordance with the above `given formula, the positions of the switches may readily be employed in electrically encoding the cumulative total of the resistance of the nonw'ithdrawn (retained) resistors, according to the binary system of number representation, and formulating a plural-element signal'representing the total. As will hereinafter become evident, the encodement can be of a number equal to the mentioned cumulative total, or of a number mathematically related to the cumulative total in accordance with a known mathematical relat-ionship. For example, the encoded number may be a specied known amount greater than,- or less than, the cumulative value1 of the retained resisators. The binary system of number representation' ploysas Va radix the number 2S, whieh is the' number of possible switch conditions (first and second) presented by the switches Sw5 Swt) after each has in its turn been moved to second position and left there or returned to first position by the previously mentioned apparatus and operations. Further, the binary system conforms to the above-indicated preferred mathematical relationship of the resistor values. As a speciiic example, if R were assigned a value of 1C ohms, R1 would be of 2C ohms value, R2 of 4C ohms, R3 of 8C ohms, R4 of 16C ohms, and R5 of 32C ohms, according' to the' mentioned formula, and according to the table: R0=C20=1C- R3^=C23=8Q R1=C21=2C R4=C24=l6C R2=C22=4C R5=C25=32C Thus, with the described apparatus any unknown value of resistance less than the sum of the R5 R0 values (63C ohms) could be measured by comparison, to an accuracy within i-.SC ohms; and the value as measured could be represented in code form with only six codey elements selected from only two types of symbols, each of the latter representing a respective one of the two switch positions. That is, any resistance value between O and 63C ohms could be represented with a degree of accuracy within i.5C ohms by a particular arrangement of only six such code elements; and it is evident that by employing a greater number of resistors similarly arranged and related, any magnitude of unknown value of resistance could be measured and encoded with a relatively small number of code elements of only two types. Extending the specific example, code types or symbols could be assigned as -F for switches in second position and for switches in first, and a measured value of, for example, 26C ohms would in code be represented by: +3 -l-, the corresponding numerical values being: 0, 16C, 8C, 0, 2C,` 0, as indi# cated in the previous table, it being recalled that a switch in iir'st position symbol) represents a rejected resistor and hence zero value.

The positions of the switches Sw5 Sw0 are in the preferred form of apparatus used to encode the meas ured resistance value by the provision of auxiliary 'circuits, one for each switch and each of which is closed by a respective one of the switches only when the latter is in its second position; and a pluralelennt signal composed of time-spaced signals elements each of one or the other of two types is formulated, using the aux; iliary circuits. One type of signal element (-f-, or posi; tive) is formed as a pulse of current through the respe; tive auxiliary circuit; and the other type of signal element A(`-, or negative) is formulated and indicated merely by the absence of a pulse' of current. Each signal ele ment has an allotted period of time; that is', a definite individual time-position in the plural-element signal. Further, as will hereinafter be evident by the tabulation of sequential operations of the apparatus, there are as many signal elements in the signal as there are com; parison elements, whereby individual signal-elements correspond to respective comparison elements. Thus each positive signal element may be assigned or repre`l sent a numerical weight or value equal to the value of its corresponding comparison element; and every nega; tive signal element will accordingly represent a numerical weight of zero since the corresponding comparison elements are those that have been rejected (withdrawn) from the network balancing arm. It is evident then that the signal elements will be spaced apart in time, those of positive sign' representing measurement values accord` ing to their respective positions in the coded signal in accordance with the preceding table, and those of nega-l tiv'e' sign representing always a zero value regardless of position in the signal. The formation of the signals will hereinafter be more fully explained in connection 'with a tabulation of sequential operations of the preferredl form of apparatus indicated on the drawings.

It is' evident that if current is applied to the input terminals of the bridge network continuously, a relatively large amount of power will be consumed. Novel means are provided whereby the bridge network has applied thereto only a brief pulse of power yeach time ay resistor or comparison element is' tried in the network, each pulse beingpreferably of a duration of the order of one millisecond'. Further, the pulses are produced by means notl including electron tubes, so the continual drain of power to operate electron tubes for pulse-producing purposes is avoided. The means for producing the bridge network energizing pulses includes a battery B3, a capacitor Q2, a resistor R10, and switches L1S5, L2S5 and L2S6, opera# tion of all of which in producing the pulses is hereinafter explained.

The pulse of current passed through the bridge network for ea'ch comparison produces across the network output terminals at junctions A and B an output pulse (unless the network is balanced), the polarity of thel pulse being dependent upon whether the bridge is overbalanced or underbalanced.- That is to say, if the corn; parison element being tried in the arrangement of parison elements then effective in the balancing arm of the bridge network is of value greater than that necessary to balance the network, the latter will be overbalanced and the output pulse will be of a rst and predetermined polarity; whereas if the comparison elementv being tried is of value insuilicient to cause the network to be balanced, the network is underbalanced and the" output pulse will be of a second and different predeter-r mined polarity. If the comparison element being tried' in the network brings the network to a condition of balance, no' output pulse will be produced when the neti work is energized. Pulses or" said rst polarity only are emploj'fed to initiate action of means including a reject' solenoid Sol, which operate to remove or withdraw' from the network the comparison element whose effec-` tive` insertion into the network resulted in overbala'neing.- Pu-lscs of the opposite'- (seco'nd) polarity, and absence of an outputA pulse, fail to initiate the described action ofl T the comparison element withdrawing means, whereby balanced or merely left underbalanced. The output pulse,'when one-is produced, is of low power and brief Vduration and of insufficient strength t-o directly actuate the reject solenoid, Sol, when necessary. Also, an outlput pulse is produced across the bridge when the network is underbalanced, in which case it is not desired to actuate the reject solenoid to return to first position the switch of the resistor being tried in the network. Hence means are provided for amplifying the output pulses, and for discriminating between those of the frst'polarity indicative of bridge overbalance, and those of the second or opposite polarity, indicative of bridge underbalance. This pulse polarity discriminating means is effective to pass only those pulses indicative of bridge overbalance, the passed pulses being usedto initiate fur- Ather operations leading to energization and operation of the reject solenoid Sol. The novel pulse polarity discriminating means is `so devised that it may also be employed as a pulse gate, whereby spurious or transient pulses, such as those resulting from oscillatory output of the pulse amplifier, are not allowed to pass through and initiate operation of the reject solenoid.

Since pulse amplification, gating, etc., requiresl the use of electron tubes, which in the normally used sizes are fragile and consume relatively large amounts of filament or heater power, special novel means are provided which permit use of normally nonconducting subminiature electron tubes, which are much less fragile and consume little power, and which special means allow such useof subminiature tubes although the instantaneous output ,thereof is of insufficient power to operatethe reject solenoid or a relay for the solenoid.

Referring to Fig. 2, which depicts in simplified form `thatpart of the apparatus and circuitry of Fig. l which is `directly involved in making resistance comparisons, and 'assuming switch SwS has been moved from first to second position, a pulse is produced across the bridge network input by sudden discharge of capacitor Q2. Q2 is charged by the potential of battery B3when a charging circuit, hereinafter described and including 73, R13, Db, GND, R24, 49, R28, Q2, 50, L2S6, 40, L1S5, L2S5 and B3, is closed by switch L1S5 each time that switch `:steps to station (10), providing both ofswitches LZSS 'and L2S6 are at one of stations (1 .'6).

Thus Q2 `.charges through the bridge network. The charging occurs during a fraction of the time L1S5 is at station (10);

for example, during about one millisecond of time. AS L1S5 thereafter steps to (11), Q2 discharges through the bridge network and R10 in approximately one millisecond, the discharge pulse producing an output potential pulse across the output junctions A andB (unless the fbridge is balanced). `A-B will produce a potential pulseiat point D of the network, which latter pulse is applied by way of conyductor 56, capacitor Q6, switch L2S4 at station (1, 2,

An output potential pulse across 3, 4, 5 or 6), and conductor 57, to the primary Winding -of an amplifier input transformer Trl. The purpose of capacitor Q6 is to prevent the natural potentialof the earth from interfering with resistance measurements. The

Vtransformer pulse produced at the secondary of Trl is iappliedby Vway of coupling capacitory Q3 to the input of an amplifier device comprising electron tubes Vtl and 'Vt2; and the amplified pulse is applied by way of capa- .citor Q5 to the control grids of a pairlofnormally nonconducting electron tubes Vt3 and Vt4` comprised inthe mentioned pulsev gate and pulse land1pulseA polarity dis'- eriminating means. The polarity ofthe pulse applied to thei control grids ofVt3 |and -Vt4 may be adjusted or ,freversedby reversing the connections to the primary of Trl. 'If the pulse applied to the grids is positive (as it will be only when the bridge network is overbalanced),

V13 and Vt4 will thereby be made to conduct, but only #5 -for switches Sw millisecond during which anode potential remains apr.

plied to those tubes. Anode potential (+45 v.) is applied to Vt3 and Vt4 during the one second `interval L1S3 is at station (10), by way of 61, L1S3 (10), 62 and +45 v. In the substantially concurrently stepped switches L1S3, L1S4 and L1S5, preliminary adjustments are made such that, as L1 steps, LlSS opens, with L1S4 opening any time within 100 microseconds priorr to -or following opening of L1S5; and L1S3 opens from .5 to .8 millisecond after L1S5 opens. Hence, the anode voltage is applied to V13 and Vt4 for only about..5 to .8 millisecond after the initial bridge energizing pulse is produced by opening of L1S5 as it steps from (10) to (11); and thus any transient after-pulses cannot be passed through Vt3 and V14 for lackof anode voltage.

In this manner V13 and Vt4 act as a pulse gate. Switch L1S4 acts through conductors 35 and 36 to short circuit a capacitor Q1 in the cathode circuit of V23 and V14, the short circuit being effective for several seconds prior to stepping of L1 from station (10). This short circuit is removed prior to reception of a pulse at Vt3 and V14, by opening of L1S4; there being a little more than 100 microseconds delay in pulse transmission time in the amplifier, etc., between L1S5 and Vt3 and1Vt4. Accordingly, if the latter tubes conduct and pass a pulse in response to overbalancing of the bridge network, capacitor Q1, now no longer short circuited, is charged through the cathode circuit of Vt3 and Vt4. Q1, when thus charged, is effective to provide a potential for the control grids of electron tubes Vt5 and`Vt6. This potential is of positive polarity and magnitude sufficient to cause normally nonconducting tubes VtS vand Vt6 to conduct. The purpose or function of Q1 isu to maintain the potential produced by the brief pulse of current through Vt3 and Vt4, for a relatively long time, whereby tubes VtS and Vt6 may be rendered conductive for atime much longer than the duration of the current @pulse through Vt3 and Vt4. In other words, Q1, Vt5 and Vt6 act as a pulse extender, stretching the pulse length to several times its original duration. The pulse provided in the cathode circuit of Vt3-Vt4 is much too brief and weak to operate a relay. Similarly, the instantaneous output of Vt5 and Vt6 is too weak to operate a relay. 3 By accumulating the output of Vt5 and Vt6 over a period of several seconds, however, enough energy becomes available to operate a relay. The charge on Q1, remaining substantially undiminished fora period of six seconds during which L1S4 steps from (10) to (11) and to (12) and on to (5), permits VtS and Vt6 to conduct@ during that time and thereby accumulate a powerful charge on -capacitor Q4, which is connected as indicated?, in the 'anode circuit of Vt5-Vt6. This charge, when permitted to pass through the coil of anfordinaryirelay such as Ry2, will operate the relay. As L1S3-,ste'ps to (5), Q4 is permitted to discharge through relayy coil RyZQ which, lthus energized, closes Ry2S1. Closure of Ry2S1 closes a battery powered circuit through the reject solenoid Sol; whereby the solenoid is operated and switch"l SwS is returned to first position to withdraw or reject the comparison element R5 from the bridge arm. Of course, if the bridge were either underbalanced or ljust balanced, no pulse would be passed through Vt3 and Vt4, jand rejection of R5 would not occur.

rIlhe previously described series of operations is, in general, repeated as L2 steps through each of stations 1(2), (3), (4), (5) and (6), but at each s tep a succeeding one of comparison `elements R5 R0 is accepted or rejected by operation of the corresponding 'one of switchesjsw .A Sw, thej solenoid Sol being successively `pedy (asjfo'rV example. by" acfionfof vswitch assem- 2),-'to returnto first position only', that switch most '.leceutiy'hlbved t`o` second position steppingqof L2. Any suitable' type `of switch assembly and reject solenoid .andactuatingmeans therefor may be employed as a unit Sw0...One-suitab1e type is that dis- "lil closedini rhs forero ritioned copendingv application of Robe Lee Alder.

I-TorrhulationV of the aforer'n'cht onecl'A signal, a's well as other' operations of the preferred embodiment of ap a'- z'itus",vv will b'e illustrated ind descr-ioctl ir'iv detailV in' con'- vviin typical i sist'arice-masfuring operation',- in

o'f the appa-rains 'may be *df values fllowing list; thr's bei-rig df value 'indicated by' goed@ design practice:

1er-6 6 veils lInf-Silvers `,1n-.6.5. .vous

.B6-13.3 volts B71.3 volts Ql-iZOO()V mmifd.

Q2-3 mfd. R21-2760 ohms mfd. 1123-2760 Ohms R042() ohms R26-3000 ohms lll-4 0 ohms E28-+400 ohms R2-80 ohms RSL-166,700 ohms Roe-2 megohmsy R4L-100 ohms T dbulalo'n f sequential operations erio'd L1 Station f. 11 This is a period marking the commencement of operations, with L1 at station (11) and L2 at (18). Flow switch Fs is closed (in this case by fluid flow in the drill string Ds). 1 12 Ll steps to (12). A synchronizing signal clement of positive type is commenced. As hereinabove indicated, all signal elements are of either pos1tive or negative type; and cach is assigned a definite period of time in the cycle of timed operations of the apparatus. synchronizing signalv elements are of the positive type, and these, together with all other positive signal elements, are initiated by respective iiowsor pulses of electric current which vare caused to flow at prescribed times. negative signal elements are initiated b y lackofau electric current ilow or pulse at prescribed times. When no current (lows in the signaling circuit at a time set cr allotted ior creation ol a signal element, a negative signal clement is thereby formulated, and mere inaction of the signaling circuit and apparatus is suliicicnt for the purpose. Positive signal elements, represented' by a current flow or pulse, are produced by electrical operation of the signaling circuit and apparatus at the prescribed periods of time. It is evident that the aforementioned auxiliary circuits, each corresponding to a respective one of switches Sw5. Swo and closed by i'ts respective switch only when the latter is in its second position, may thus be employedasprimary controlling means for the signal circuit in formulating the pluraliclement signal representing the measure of the unknown value of the physical quantity. As will be made clearly evident hereinafter, the auxiliary circuits are also closed in timed sequence by switch L2Sl, to correctly time or space the signal elements in the signal. In the disclosed exemplary embodiment of apparatus, a signaling device in the form of an electromagnetically actuated valve V is provided (Fig. 1), the valve'having an operating magnet coil Vc to receive and utilize the aforementioned periodicf'flows of electric current, to produce flow or pressurechanges in a drilling iiuid stream in the drill string Ds.V The synchronizing signal-element iS DIOucedrby actuation of valve V by current flow through the following circuit: B2, 30, L2S7(18), 3l,'L1S6 (12,-.1S and 2), 32, Vc and GND; at a time governed b y Ll'S. The flow oi'pressure' change produced 1n the stream of drilling .fluid .flowing downwardly through drill string Ds is quickly transmitted thereby toau accessible point near the top ot the drill string outside the borehole'. It is there da tected and translated by suitable ASignal receiving and translating means (not shown) which may be oi conventional design and comprseprincrplly a pressure transducer and a recorder Lconnectedto receive and be' regulated by zmd record the output of the transducer. v

renee L1 station 14Y te 16.. 1v to 3 17 4 is 5I 'cut oi from the' signaling circuitand Vc asY LIS 3 .steps from (2) to(3). v Idle period, separating creation and transmission oi the firstv synchronizing signal element from other actions offthe' appautatus. l.

L2 is stepped from (18) to (l), theenergizing circuit being through L1S2 as hereinabove indicated. Steppingof L1 to. (4). and L2 to (1) prepares the apparatus. controlled by L2 for the initial steps of the operations of measuring the unlmown value of resistance, encoding a number. representing the value Aas measured, and formulating a number- 'representingsigna1- As L2 is stepped to (l), Sw5 is actuated from rst'position tov second position, removing the. short-circuit from Rand thus electrically inserting R5 into the balancing arm of the bridgenetwork Br. Atthe samctnnc, themoved part of SL05 closes or causesclosure of the associated auxiliary circuit at that p oint.

L1 S4 in stepping to (o) s hortcircuits capacitorQl, which shortcircuit remains Veffectivev substantially until L1' subsequently steps from (10) to (11)-, as hereinabovenoted. |lhe short circuit is by 'way of Q1, 35, L1S4(5) and.

As L1 steps to (6), a second syichronication' signal element yis commenced-,- thev circuit .bein'gz G ND, V,.32 Llsw), 37, L.2..S 1(1), 6.8 3.9, B,2 (,|30 VPIS) and GND'. .'lhi's signal element continues while LlSG is atstations (f), (7) end (s), and constitutes the second three-second synchronization signal element.

Continuation of action of period 7.

Continuation o'f a`ction of period 7, and termination of the synch signal element at the end of this period.

. Idle period. i As L1 steps to (10), LlS5 at (10) closes a circuit which permits battery B3 to charge capacitor Q2lin` preparation for production yof an bridge network. The charging circuit' is: B3, 42, L2S5(1), 41, LISS, 40, L2S6(1), 50, Q2, on oneA side, and Q2, 1228,49, R24, GND, Db, maf/3, 44,- and 43 to B3 on the ,other side. Q2 charges in about one millise'cond of time. i pulsev across the'A bridge output circuit is of course produced atthis time, but it is of n'o consequence since, among other things, LlS4'iss1ort circuiting capacitor Q1 kso that no effect is produced in Vt5 and Vio. The.pulse to be employed in energizing the bridge network for measurement purposes is that produced by dischargeof Q2, as hereinabove noted.l During this period, anode potential (of 45 volts, for exle)disap'plied to VB and Vt4through 61, L1S3- an 2. Switches L 1 S3, LlSe, and L l'S have b ec n adjusted as previously described. In stepping .from station (l0), Ll-SS opens from. .5 to .8 of a millisecondi' after LlS opens; and L1S4 opens no later than 4100 microseconds -after L1S5, so Q1 is uns'norted prior to possible arrival of apulse at V153 and Vt4. As L1S5 opens, Q2 dischargesV and the bridge network is pulsed or energized with comparison element R5 in the balancing arm. Since the unknown value o1' resistance is in this assumed case- 850 ohms and R5, is.640 ohms, 'a negativep'ulse arrives a't V153 and V14 and fails to pass therethrough, those tubes being alreadybiased to rcut-od. Hence the reject solenoid Sol will not be operated and Sw will remain in its second position.. leaving R5 accepted (nonwithdr'awn) and electrically connected in-thc balancing arm' ot they bridge. Sw ill thus keep closed the auxiliary circuit connection between conductors 39 and 38, us`ed later in period 19 inr'eading out the R5 comparison value of 64D ohms and in formulating Va,n1easurcmeutrepresentingsignal element corresponding to Szi=5 and R5. LlSl at ,this time opens its .portion ofthe main power supply circuit, so if flow. switch .Fs is open the apparatus will cease tooperate untily F.: again closes. .It is assumed throughout that Fs remains closed. Idle period. Idle periods. L2 is stepped from (1) to (2) as L1 S 2, at (4),closes the circuit to supply stepping power to L20. ns L2 steps to -(2)-, Swil is moved from nrst position to second position (opened) by L2, and the reject solenoid Sol is repositioned for possible coaction with S104. y A ctuation o'f S104 closes at. that point the auxiliary circuit including si? and 60, for. subse quent signal circuit energization if comparison elenent R4 is accepted and retained in the networ again shor'ted, as in period 6, by L1S4',.35 and 36. The' cireuitthrough Ry2 G is closed for discharge o f Q4 by Ll S3. No discharge occurs in this instance, however, since no `p ulsewas passed by Vt3- Vt4 in period 12 and Q4 Wasthercfore not charged. Reject solenoid SolisA accordingly not energized and does not operate at this' time encrgizingpulse for the Period stl# Period stlli.

a ion a on 19 6 L1 Steps t0 (6) and a DOSitiVe (l) information-repre- 5 translation it is again to be noted that any negative senting signal element (the first element of a slxsignal element represents a value of zero only, since element signlal refpreseiting) the; meauredo the corresponds tot a 7isiitlldrawn 1:comrIiLarison elelrent. unknown va ueo resis ance is orme an rans- 2 eing nowa eresis ors are mitted. The signal is transmitted by in this electrically severed from the bridge network by example, a flow of current and operationoi valve L2S3, which is now open; and until that switch V by energization of Vc causing a fluid flow change steps to (10) and again connects those resistors in in the drill string, the current being supplied circuit, further bridge network measuring operabTOllgh the Circuiti +30 V, 39, S105 (110W in 10 tions are precluded. Also, as L2 steps to (8) at the second position and connecting 38 and 39), 38, end of the interval, signaling is precluded for a 36- L2S1(2), 37, L1S6(G), 32, Vc and GND. second period during which L2 is at (7), (8) and 20 7 Ll steps to (7) and the irst information signal- (9). This interval is used to separate, in time, the element COllilllLleS- This Signal @lement H8- information signal representing a resistance sponds to Sw and R5 and is related in time semeasure, and a signal of a second information (11161108 t0 the actuation 0f S105 and the DOIlWithchannel and in this example representing ameasurc drawal oR. oi an unknown" value of voltage or potential.

21 8 As in period 20, the signal element ending with the In the example hereinafter employed in explaining end of this period. The rst signal element (posithis feature of the operations, the unknown potive in this example) is definitely spaced in time reptiel will be assumed to be that of e portion oian 18 seconds after the commencement of the rst earth formation adjacent an inaccessible location SYllChTOllZatiOll Signal element, and 12 seconds in an earth borehole, with respect to an electrode after the commencement of the second synchrorepresented by drill bit Db, affixed to the lower end nizatioii signal element; and, like the other signal of drill string Ds. elements, is of substantially three seconds dura- 20 tion. As the first signal element of the first information signal, it carries aweight of C25, equal iplthis spiinorleaitngie tg fiohthei reietyemiirilitnio The hereinabove described part of the apparatus is vaueo ai we esgna e is received at th? accesible point bemgjhe first with only slight modifications employed in an automatic elmentdoftheiormatonlgnlndposltlvetis compensating volrmeter capable of accurately measurrecor e or o erwise eva ua e as represen ing a am V of C2=C2s=320, o in tins example 25 ing voltage values of sources of either high or low in bleile ettigailntgogooaneigli)iagtlvienal `ternal resistance; and, as in the case of the previously ee en e c rr a 22 9 The discharge path for Q4 ,s opened as 1,153 steps described resistance measurements, of encoding a num fmnl) etche ld Ofthls Penod'pfepfmg Qlfol ber equal to or representative of lthe voltage value, and possi e arg g.

23 io Piate potential oi 45 v. is eppiied to vrs end vn vformulating a coded signal representing the number and through 61 1115300), and 62 uffellt 1S Sgam 30 value. Further, this type of operation is conductedwith supplied by B3 to recharge Q2, as in period 11 here- .1 1 t Ower In arran in the a inabove. As I lS steps from (1 0) Q21s discharged Simi ary grea- SaVlngS 1U P g g P thmughthe budge network Whlqh 110W mchldesm paratus to perform this function it is only necessary to tile baltaiisiugd armi 'mbt hemmed comliarisont so connect resistors R5 R0 that a comparison quan e einen an new ymser e comparisone emen R4. Since these two resistors in series total 960 i ohms, the bridge network is, by insertion of R4, 35 uw or Voltage. 1S deYeloped acrss eah ndslrgport (na overlipaatnceclgand asui resiilaiposilnve inisetls to the respective resistances, using switc es v w appie o an an scarge in e manner hewinabove xp1aned- W5 and W6 and their actuating mechanisms as before, and of course pormoiifbiasedbeyond outoiaindhnoinoinauty it is necessary that the unknown voltage be so added noncon uc ing,now areren ere con uc ive ue o s ed no m m that frisia-ahr to a ove cu o v ue; an commences proper p0 ari cs are i 1 e 4 charging. A 40 i 24 u The ac cumulmon ofcharge by Q4 continues or may Thus the connections are made such that when the com olpstpspbittgienitiltli grieiilillyQhigge/eggi parisou voltage exceeds the unknown voltage which it is to Overcomenthe mmalngave grid bias on W5 connected to oppose (that is, ovcrbalances the poten- 25t 2S mt 3 Aena vie diung all of this six-second interval. tiorneter), the same conditions prevail as obtained when o o sin peno 9 4 L2 steps to (3) moving Sw3 to itssecond positionand the b flqge Was overbaland. m measuring feslstan, thus inserting R3 1n the balaems aun 0i the bridge 45 and similarly, when the opposing voltages are equal, cormm'og' Chargng @m4 may continue lres ondin to the condition of bridee balance no ulsc is o 5 Q1 is again short-circuited by L1S4. Q4 discharges P g C e a P through R100, CallSlIlg Opeftwn Qlrelect Solelwld applied to the amplifier, and when the unknown voltage Sol which in operating returns switch S104 to first d t1 1t th t position. The return oiswitch S w4to rstposition excee S 'le compaflson V0 age e appara us ac S as again short circuits and thus reiects or withdraws when the bridge was underba1anced keien-mg option. mdfiom thfegalaulgarm-0f 'hilnidge network; 50 ally to Fig l or Fig 3 which is a simplied circuit dia an eaves all 111 SeilES ln 8. arm. s l

y Y o pass cur'reh; m'ldthe resultamlak of @ment and 55 plied to the following ser-ies circuit including the com. oi encrgeiaioi oigll/lcalateiglscnrliog tgliriiis parlSOn element resistors. R30, 70, LZS3(1015), 47, 111 a Il a 1V Sl When the receiver at this time fails to detect a 71 72 1 {0 R12 R2 R3 R4 R5 45 44 and a Selected loisiltilvge elemeiigtrinothvihcxsgfaeclagl )oei one 0f high resistance IeSlStOi'S R31, R32 and R33 (R31 l i ui o a e rilecordc or registered for this particular signal as Due the hl relslance of Til/ 11:21 Tg1 Semen 60 Spec O a. SU S an la y COl'lS all lIl lVl U 34 tn 1 9 to S During this extensive interval the above-described operations areingeneral'l-epeatedmstepping one voltage drop exists across each o'f the latter (when in step s211221? cgmpatrlsoili cslleb 1R3, R2, Rl iand B0 the circuit) regardless of jthe insertion in or removal from are eac in urn ne in e aancing arm nseries 4 i ,i with pi-eviousiy'retained resistors, bypreviously the circuit of one or more thereof. These. standard geslcubeddsopratwills, liclitldme ttltwn osull or comparison voltages, which are of differing interreexample' resgms R3 and m are accepted as was 65 lated values according to the ohmic values lof the re- R scaiildaesisolrs4 R2Ti1i1n tlgrreitgggvptg .spective resistors, are in sequence tried, each in its turn, le] e la l1 end of. period' N0 80, and with the tepmnatiop of lll 'OppOSltlOl'l .t0 the llllkIlOWn Voltage by COIlIleClOIl lll the SIXt-li s151181 element 0f tlle- 111f01'mat1911- series therewith as will hereinafter be explained.l To iresuu lzmh'f lgtefogtgl enable the apparatus to cover a wider rangeiof 'unknown mined plural-element signal consisted of the. potentials, a third known voltage of regulatable value .is following arrangement of positive and negative t d d th a Th l tt 1 demgnts; T Translatlng these ele- 1n I'O uCe 1n e Sel'leS arral'lbement. C a er V0 t ments by asslgnmg t0 eaPh the Weight 0r Value age is created across a selected number of a bank of ve assigned to the corresponding comparison elements es iereiolbeior ildioatg use ineiislragsiatd resistors, R41, R42, R43, R44 and R45, by a battery an eva nate us: y i integrating or adding the Several v'alu'es, me signal B7, the circuit constants being such 4that a range of volt is round to represent 84o. In performing this l'15 ages about equal to tha-tto be covered is produced across 15 'the group; For example, 100 mv. drop is produced across each yof R41 R45 when the constants 'are as listed in the previously set down table.

As a result of the circuit arrangements described and indicated, a circuit is closed when LlSS is at (10) as indicated in Fig. 3, which permits all the three mentioned voltages to be effective in a series circuit including the primary of Trl. Hence, if the unknown voltage is not balanced Iby the others, a current willl ilow through Trl (pri.) and when L1S5 steps from 10) to (11) the circuit will be opened and a pulse will be produced in the secondary of Tr1. The polarity of the pulse will be dependent upon whether the unknown potential is greater than, or less than, the voltages it opposes. (In this instance, as when resistance was being measured, an initial pulse is produced when the circuit is closed, but this initial pulse is equally ineffective. The active pulse is that produced when the circuit is opened at L1S5.) The current carrying series circuit is: Trl (pri), GND (as represented by the drill string), the earth, Db, R13, 73, 45, R (Sw5 being at this time in second position), Sw4 Sw0, 72, 71, 47, L2S3(10-15), 70, 74, 75, R41, 76, L2S5(1015), 41, L1S5(10), 40, L2S6(1015), 77, `L2S4(1()15), and 57 to Trl (pri). The three voltages in the circuit are those across R41, across R5, `and between Db and GND as represented by an exposed uninsulated part of the drill string, which is insulated from Db as indicated. The polarities are so arranged by circuit connections and by positioning polarity shifting switch Swll that if the comparison voltage across the comparison lelement (in this case R5), is so high that the unknown potential is overcome, a pulse will pass through the amplifier and the pulse discriminator, and cause the reject relay and reject solenoid So1 to return SwS to first position.

If the unknown potential is not overcome, a pulse will not be produced at the output of Vt3-Vt4, and the solenoid will not be operated. The indicated procedure isA repeated for each of the other comparison units R5 R1 and R0, each in its turn, in a manner evident from the previous description of the resistance measurement procedure. In other respects the apparatus operates in a manner similar to that described hereinabove with respect to measurement, etc. of an unknown value of resistance, L1S5 switching on the current when it reaches and cutting o the current to create the pulse as it steps from (10) to (11). L2 is stepped through stations (10) (15) during the interval consuined in making six potential comparisons; and a pluralelement signal repcrsenting the effective comparison value is formulated and transmitted as L2 traverses stations (11) (16), in an obvious procedure.

Following measurement, encoding and signaling of a number representing the unknown value of potential, the apparatus introduces a 27 second spacing period during the time L2 is at (16), (17), and (18), prior to recommencement of the complete cycle of operations thus far described. Thus two channels of information are transmitted, each in its turn, in the manner of time-division multiplex signaling, in each 216 second interval. The entire before-described sequence of events is automatically and cyclically repeated, to provide a continued series of measurements and measurement-representing signals. It should be noted that after the lirst comparison or trial of a comparison element is effected (in this case the trial of R5 or the voltage thereacross), succeeding comparisons are rnade in which against the unknown value there is compared an arrangement of one or more comparison elements. lf only one comparison element is in the arrangement, that comparison element is by itself opposed 'to the unknown value to be measured; but if there has been a previous trial `and retention of a comparison element, then the arrangement will include one or more comparison elements. Thus the actual comparison that is effected when a given comparison element is tried in the comparison network is that of a variable arrangement of comparison elements, with the unknown value. The variable `arrangement may be composed of but one, or of two or more, comparison elements.

Whilein the specific embodiment of apparatus herein employed to illustrate a system and mode of operation according to the invention, comparison elements or quantities in the form of resistances and voltages were employed, it is evident to those skilled in the art that other types of comparison elements or quantities may be employed. Further, while for convenience of illustration the comparison elements were chosen so as to be interrelated according to a particular mathematical system of number representation known as the binary system, so advantages inherent in a signaling system employing only two types of signal elements could be secured; it is evident to those skilled in the art that other mathematical number-representing systems may be utilized. It was noted that with six comparison elements Aand employing binary notation and values, a range of unknown quantity values of from 0 to 63C could be vmeasured to an accuracy within tLSC, However, by increasing the number of comparison elements any desired range of unknown values may be encompassed. Also, by choosing the value of the lowest-valued comparison element small enough, any desired degree of accuracy may be attained in the measuring operation. Thus the measurement of an unknown value may be effected with extreme a'ccuracy. The number encoded by the apparatus is seen to represent precisely the value as measured. 'Ihe number may be either the actual value as measured, as in the resistance measurement hereinabove tabulated in detail; or it may be that value plus or minus a given amount or otherwise definitely related to the value in accordance with a known mathematical relationship, according to comparison network component values. The signal formulated and transmitted represents quite precisely the encoded number. The system, by employing brief pulses of energy for network energization and normally nonconducting sub-miniature electron tubes in the novel circuitry, attains remarkable economy of operation while attaining extreme accuracy in measuring and signaling.

Also, itshou'ld be noted that while in the preferred embodirnent of apparatus r'according to the invention the comparisonjelements are connected into a variable arrangement thereof wherein the several elements are connectedin series, other configurations and types of connections may be employed within the spirit of the invention. Forms of switches 'and other apparatus components diiferent from those diagrammatically illustrated may be employed.

Since modifications of the disclosed apparatus and method have hereinabove been suggested, and others will be evident to those skilled in the art, it is not desired to be limited to the specific details of the preferred embodiment of a system according to the invention, but what is claimed is:

l. Means for producing and transmitting a signal indicative of the value of a physical quantity, comprising: an electrical bridge network having an input'connection, andoutput connection, and two arms,the first ofwhich arms is connectable across an electrical circuit having an electrical 'characteristic representative of said value; a plurality of separate circuit elements, each of fixed different lelectrical characteristics; means to introduce each of said separate circuit elements sequentially in series into said second arm; means responsive to the output from the said output connection as effected by overbalance and underbalance of said bridge network7 when energized through said input connection, to maintain such of the thus introduced circuit elements in series in said second arm as Vresults in underb'al'ance of said bridge network and to reject and remove such of the thus introduced elements from said series connection in said second arm as result in overbalance of said bridge network; and means responsive to 'the action of said last mentioned means to produce and transmit-.a signal'pulse each vtime 'a circuit element which is thus introduced in series into said second arm is not rejected and withdrawn therefrom. and prior to the next sequential introduction of a circuit element into said second arm.

2. Means for providing and transmitting a signal indicative of the value of an electrical resistance, comprising: an electrical bridge network having an input circuit, an output circuit, and two arms, the rst of which arms is connectable across said resistance; a plurality of resistance elements, each of iixed diierent values; means to introduce each of said separate resistance elements sequentially into the second of said arms; means responsive to the output from the said output connection as eiected by overbalance and underbalance of said bridge network when energized through said input circuit, to maintain such of the thus introduced elements in said second armas result in underbalance of said bridge network and to reject and withdraw such of the thus introduced elements from said second arm as result in overbalance of said bridge network; and means responsive to the action of said last mentioned means to produce and-transmit a signal pulse each time a resistance element which is thus introduced into said second arm is not rejected and withdrawn therefrom and prior to the next sequential introduction of a resistance element into the second of said arms.

3. In an earth borehole investigation system including a drill stem, apparatus for determining the unknown value of an electrical resistance therein comprising in combination: an electrical resistance bridge network in said drill stem having an input circuit, an output circuit, and two arms, in a iirst of which arms is connectable said resistance of unknown value to be measured and in a second of which arms is connected an opposed balancing means including a plurality of resistance elements, each of fixed dierent value and connectable in series; a plurality of individual, two position switches one of each associated with one of said resistance elements and arranged when in a irst position to remove the resistance thereof from said balancing means and when in a second position to introduce the resistance of said resistance element in said balancing means; means sequentially and at uniform time intervals to move each of said switches from its said tirst position to its said second position; means to energize said bridge network by a brief pulse only of electrical energy following each such movement of each of said switches from its said irst position to its said second position, to produce a bridge network output pulse of a iirst polarity if such switch movement to such second position results in introduction of such resistance in said balancing means as to overbalance the bridge network, and of a second polarity if such as to result in underbalance of the bridge network; means responsive to only output pulses of said rst polarity to return such switch from its second position to its said rst position to remove the resistance of the overbalancing resistance element associated therewith from said balancing means of said bridge network; and means to produce a signal pulse in said drill stem substantially immediately following each of said movements of said switches to is respective second position and which results in introduction of a resistance in said balancing means which results in underbalance of said bridge network such pulse occurring prior to the movement of the switch associated with another of said resistance elements to its second position, whereby a signal is produced in said drill stem each of which is composed of a plurality of time spaced pulses indicative of the unknown value of said electrical resistance.

4. In an earth borehole investigation system including va drill stem, apparatus for determining the unknown value of a physical quantity therein comprising in combination: a bridge network in said drill stern having an input circuit and an output circuit and two arms, in a first of which arm is connectable an electrical circuit having electrical characteristics representative of said unknown value to be measured and in a 'second of which varms is connected and opposed balancing means including a plurality of circuit elements, each of xed different electrical characteristics and connectable in series in said balancing means; a plurality of individual, two position switches one of Veach associated with one of said circuit elements and arranged when in a iirst position in effect to remove the circuit element from said balancing means and when in a second position in effect to introduce the circuit element in said balancing means; means sequentially and at uniform time intervals to move each of said switches from its said iirst position to its said second position; means to energize said bridge network through said input connection by a brief pulse only of electrical energy following each such movement of each of said switches from its said iirst position to its said second position, to produce a bridge network output Vpulse from said output connection of a rst polarity if such switch movement to said second position results in introduction of such circuit element in said balancing means as to overbalance the bridge network, and of a second polarity if such as to result in underbalance of the bridge network; means responsive to only output pulses of said rst polarity to return such switch from its second position to its said irst position to remove the circuit element associated therewith from said balancing means of said bridge network; and means to produce a signal pulse in said drill stems substantially immediately following each of said movements of said switches to its respective second position and which results in introduction of a circuit element in said balancing arm which results in underbalance of said bridge network such pulse occurring prior to the movement of the switch associated with another of said circuit elements to its second position, whereby a signal is produced in said drill stern each of which is composed of a plurality of timespaced pulses indicative of the unknown value of said physical quantity.

5. In an earth borehole investigation system including a drill stem, apparatus for determining the unknown value of an electrical resistance therein comprising in combination: an electrical resistance bridge network in said drill stem having an input circuit, an output circuit, and two arms; means in the drill stem for connecting a iirst one of said arms across said resistance of unknown value to be measured; means in the second of said arms for connecting it across a variable resistance means adapted by variation of the value thereof to effect either an overbalance or an underbalance of said bridge network, said variable resistance means including a plurality of separate series connectable resistance elements each of a predetermined different fixed value; means to introduce each of said separate resistance elements sequentially into said variable resistance means; rejection means actuatable separately to remove each of said thus introduced resistance elements from said variable resistance means following its introduction thereinto; means to energize said bridge network through said input circuit by a brief pulse only of electrical energy following each such sequential introduction of each of said resistance elements into said variable resistance means to produce a bridge network output pulse from said output circuit of a first polarity if such introduction of such resistance element results in overbalance or of a second polarity if such introduction of such resistance elements results in underbalance of said bridge network; means to actuate said rejection means only in response to output pulses from said output circuit of said first polarity to remove any of said introduced resistance elements from said variable resistance means the introduction of which results in overbalance of said bridge network; means responsive to each such introduction of a resistance element which does not result in overbalance of said bridge network to produce a signal pulse in said drill stem, such pulse occurring prior to the next sequential introduction of a resistance element into said bridge network, whereby a signal is produced in said drill stem composed ofla plurality of time .spacedsignal-pulses indicative of the unknown value of said electrical resistance.

6. Means for producing and transmitting a `signal indicative ofthevalue of an electrical potential, comprising: an'electrical potentiometer network having an input connection, ,an output connection, and two arms, the first of which arms is connectable across said electrical potential; a plurality o f separate potential varying elements, Such offixed different characteristic; means to introduce .each

of said separate potential varying elements sequentially in series into said second arm; lmeansresponsive to the output from the said `output connection effected by overbalance and vunderbalance of said potentiometer network, when energized through -said input connection, to maintain such of the thus introduced-potential varying elements in series in said second arm as results in underbalance of said bridge network and to reject Vand remove such of the thus introduced elements from said series connection in -said second -arm as results in Yoverbalance of said potentiometer network; and means responsive to the action of the ,last mentioned means to produce and transmit a single pulsefeach time a potential varying element which `20 `iszthr'ls 4introdllcnd in eseries into said :second arm is l'not rejected `andwithdrawn therefrom land vprior -to the nextsequential introduction of.a potential varying element into saidzsecond zarlm. 4

= -Rejierences Cited vinthe -le offthis vpatent UNITED .srArEs .RATENTS i 502,399V Haskins Aug. 1, 1893 1,783,234 'Firestone Dec.. 2, 1930 2,008,512 -M01ack luly 16, v1935 2,023,221 'Eischeretzal. Dec. 3, 1935 2,030,794 Horton `Feb. 11,193.6 2,207,743 Larson :et al. July 16, 1940 2,354,887 Silverman .Aug4 1, `19.44 2,466,746 Shive Apr. 1'2, 1949 2,467,856 Rich Apr. Y1-9, '1949 .2,531,145 Marco etal. Nov. 21, :1950r` .2,633,019 Albrecht et al Mar. 31, 1953' 2,680,808 Nolde June 8, 1954 2,700,131 Otis ,etal I an. 18, 1955 Arps, Aug. 14, :1956

DNTTED STATES DATENT EETCE CETEFACATMN l@ @AAEC'HN Patent No 23973V5O5 February 25g 196A Oddvar MQ Johenneeen It is hereby certified that error appears in the above numbered patent requiring correction and that the seid. Letters Patent should read as corrected below.

In the grant (only) U line 1v neme o' TATA/enten? for "'Oddyar M., Johannesen read m Oddver Ma J'ohenneeen die; in the printed specificnmonQ column l()U line 759 for ""Swo n SWO read @e Sw5 .,SWO me@ column 11V in the Detlev column. 3 thereofEI for '(12Z 1S" reed (12V l column. 13u in the tnbleU Column l thereof@ for the period number 3Q to l" reed fm- 34 to 8l en; column 19V line 81I for Neneh reed eeen 1w.

lzne 46 Signed and Sealed this 5th day of September 1961.,

(SEAL) Attest:

ERNEST W. SWTDEE l DAVID E. EADD Attesting Officer Commissioner of Patents UNITED STATES PATENT TTTCE @E 'TEMQMFMN E @@ECTMN Patent. Noo ei'zeveoe fehmary 2&3, 1961 OddT/ar Mu Jehannesen It is herebg)T certified that error appears in the above numbered. patent requiring correction and that t he seid Letters Patent should read as corrected below.

In the grant (only) U line lV name ei m'ventma for "'Oddyer M,s Johan'nesen" read m Oddvar Mo nehuarlheeen Se; Tn the printed speciiicatllola9 column l() line 75V for mSwc a oSWOY" Teed @e Swo o Sw me@ column llQ in the tableg eelumn 3 line 46 thereon for U(l2 1S read (l2Y l column 13v in the tableq Column l thereof) GT the period number '3@ to l" reed w 34 to 8l eng column 19B lime 8 fof Neneh read each un Signed and sealed this 5th dey of September 1961.,

SEAL) Attest:

ERNEST W. SWIDER v DAVID L. LADD Attesting Officer Commissioner of Patents 

